RU232223U1 - COMMUNICATION FIRE ARRESTER - Google Patents

Abstract

The utility model relates to the energy, chemical, oil and gas, coal industries, in particular to fire-fighting devices used to prevent the spread of combustion through pipelines transporting an explosive product, including with an increased flow rate, with simultaneous relief of the pressure of the explosion shock wave. The communication flame arrester comprises a housing with flanges consisting of at least one input and at least one output tee, between which at least one flame-extinguishing element is located, and at least one explosion safety valve is located on the free opening of the input and/or output tees. The flame-extinguishing elements of the communication flame arrester are additionally provided with compensators. The housing of the communication flame arrester can be made in the form of an input manifold and an output manifold, between which the flame-extinguishing elements are located.

Description

The utility model relates to the energy, chemical, oil and gas, and coal industries, in particular to fire-fighting devices used to prevent the spread of combustion through pipelines transporting explosive products, including those with increased flow rates, while simultaneously releasing the pressure of the shock wave of an explosion.

A communication flame arrester is known (RU Patent for Utility Model No. 106123, priority date 14.02.2011, publication date 10.07.2011 in Bulletin No. 19, IPC class A62C 4/00), consisting of a housing with inlet and outlet pipes with flanges and at least two flame arresters. Moreover, the flame arresters are arranged in relation to each other in such a way that they can rotate in different directions relative to a common axis, which leads to the destruction of the detonation wave, its energy is converted into the rotational energy of the flame arresters. The pressure decreases, and further localization of the fire is ensured by the mechanism of extinguishing deflagration combustion in narrow channels of the flame arresters. In addition, the prototype provides gaps between the flame arrester body and the flame extinguishing elements, the size of which does not exceed the value of the critical extinguishing diameter.

The disadvantage of the known communication flame arrester is that the first flame arrester in the direction of the shock wave creates significant resistance to the propagation of the shock wave. At high values of the speed and pressure of the shock wave, it can destroy the housing of the communication flame arrester before its energy is converted into the rotation energy of the flame arresters. It is also difficult to maintain the size of the gaps between the housing of the flame arrester and the flame arresters, not exceeding the value of the critical diameter of flame extinguishing and sufficient for the rotation of the flame arresters.

The prototype of the claimed utility model is a communication flame arrester (RU Patent for Utility Model No. 195092, priority date September 16, 2019, publication date January 15, 2020 in Bulletin No. 2, IPC class A62C 4/00), comprising a housing with an inlet and outlet pipe with flanges, consisting of an inner and an outer part, wherein the inner part of the housing is a continuation of the inlet pipe and at least one flame arrester is located on it, and the outer part of the housing is connected on one side through a truncated cone to the outlet pipe, on the other side - through an annular plate to the inner part of the housing, while at least one explosion safety valve is located on the outer part of the housing.

The disadvantage of the prototype is that the flame arresters are located on the inside of the flame arrester, which complicates access to them, their installation, and maintenance. When operating flame arresters in difficult conditions, in the presence of moisture and/or solid inclusions in the transported flow, the flame arresters are subject to frequent clogging due to the presence of narrow channels, therefore they require periodic cleaning and replacement, which is difficult for the prototype design. It is necessary to disassemble the outer part of the housing to access the flame arresters, especially the flame arrester located on the end of the inner part of the housing, which increases time and labor costs.

The technical result of the proposed utility model is an increase in the reliability of the communication flame arrester.

The specified technical result is achieved by the fact that in the communication flame arrester, containing a housing with flanges, flame-extinguishing elements, according to the claimed utility model, the housing consists of at least one input and at least one output tee, between which at least one flame-extinguishing element is located, and at least one explosion safety valve is located on the free opening of the input and output tees. Also, the flame-extinguishing elements of the claimed communication flame arrester are additionally equipped with compensators.

The claimed utility model is explained by drawings, where Fig. 1 shows the claimed communication flame arrester with five flame-extinguishing elements, which can be installed horizontally (Fig. 1 is shown as a top view), or vertically (Fig. 1 is shown as a side view), Fig. 2 shows the claimed communication flame arrester, in which the body is made in the form of an input manifold and an output manifold.

The claimed communication flame arrester (Fig. 1) consists of inlet tees 1 with flanges, outlet tees 2 with flanges, flame-extinguishing elements 3, explosion safety valves 4. The inlet tees 1, as well as the outlet tees 2, are fastened together by any known method, for example, by welding or a flange connection. The explosion safety valves 4 consist of an easily removable membrane 5 made of a non-combustible material, a mating flange 6 pressing the membrane 5 to the flange of the inlet tee 1 and the flange of the outlet tee 2 at their free openings. The claimed communication flame arrester is installed through the flanges of the inlet tee 1 and the outlet tee 2 to a pipeline (not shown in the drawing), through which an explosive product is transported, and ignition and/or explosion may occur. Fig. 1 shows the expected direction of transportation of the explosive product. The design of the claimed communication flame arrester may include hatches 7 for monitoring and cleaning flame arresting elements. Also, flame arresting elements 3 of the claimed communication flame arrester are additionally equipped with compensators 8.

The body of the claimed communication flame arrester (Fig. 2) can be made in the form of an input manifold 9 and an output manifold 10, between which flame extinguishing elements 3 are located.

The principle of operation of flame-extinguishing elements 3 is based on extinguishing the flame by means of heat exchange in small-diameter channels, smaller than the critical flame-extinguishing diameters for various flammable and/or explosive mixtures. The flame, entering small-section channels, is broken up into separate small flows. The contact surface of the flame with the flame-extinguishing element 3 increases, heat transfer to the channel walls increases, and the combustion reaction ceases. The designs and materials of flame-extinguishing elements and flame arresters in general are described in the book by Kovalchuk R.M. Fast-acting flame arresters. - M.: NIITEKhIM, 1977. - 92 p., in the book by Strizhevsky I.I., Zakaznov V.F. Industrial flame arresters. - M.: Chemistry, 1974. - 189 p. The flame-extinguishing element 3 can be made of alternating corrugated and flat metal tapes or a set of meshes superimposed on each other, which is not the subject of this utility model. Thus, any of the known materials and designs that ensure the free passage of an explosive product but prevent the spread of flame can be selected for the manufacture of the flame-extinguishing element 3. The number of flame-extinguishing elements 3 is determined depending on the required throughput of the pipeline at the installation site of the claimed communication flame arrester.

The principle of operation of explosion safety valves 4 is based on the release of excess pressure of ignition and/or explosion that has occurred in the pipeline through which an explosive product is transported. The easily resettable membrane 5 made of non-combustible material is designed for a certain pressure, at which it is destroyed (torn) or flies out of the flange of the inlet tee 1 or the flange of the outlet tee 2 and the mating flange 6 that press it. The arrangement of explosion safety valves 4 on the free openings of the inlet tee 1 and the outlet tee 2 ensures protection against destruction of the inlet tees 1, outlet tees 2 and flame-extinguishing elements 3 by releasing excess pressure of ignition and/or explosion that has occurred in the pipeline along the path of least resistance.

Compensators 8 can have any design and materials, they can be, for example, bellows, fabric or tubular, which is not the subject of this utility model.

The claimed communication flame arrester operates as follows. Under normal conditions, an explosive product transported through a pipeline enters the cavity of the inlet tees 1 of the claimed communication flame arrester, moves through the flame arresters 3, enters the cavity of the outlet tees 2 and then continues to be transported through the pipeline. When a fire and/or explosion occurs in the pipeline on either side of the claimed communication flame arrester, a shock wave, entering the cavity of the inlet tees 1 or outlet tees 2, is ejected outside through easily resettable membranes 5 of the explosion safety valves 4, designed for a certain pressure. As a result of the release of excess ignition and/or explosion pressure, the claimed communication flame arrester and the pipeline are not destroyed. The flame moving behind the shock wave hits the flame arresters 3 and is extinguished in its narrow channels.

The claimed arrangement of the input tees 1, output tees 2 and flame-extinguishing elements 3, as well as the explosion safety valves 4, ensures unimpeded hermetic transportation of the explosive product under normal conditions, creating only minor resistance on the flame-extinguishing elements 3. When ignition and/or explosion occurs, free release of excess pressure occurs through easily resettable membranes 5 of the explosion safety valves 4, the flame-extinguishing elements 3 extinguish the flame, preventing its spread along the pipeline with the explosive product and the development of the explosive process. In this case, the claimed communication flame arrester has standardized standard elements, the number of which is determined only by the required throughput and the cross-section of the pipeline through which the explosive product is transported.

Thus, the claimed communication flame arrester has a simple design consisting of widely known elements, reliably performs the functions of extinguishing the flame and relieving the explosion pressure to prevent the destruction of the claimed communication flame arrester and the pipeline through which the explosive product is transported. At the same time, the claimed communication flame arrester is easy to install and maintain. Flame extinguishing elements can be easily inspected and washed from contamination through hatches, for example, by supplying water under pressure. They can be freely removed one by one for replacement or repair, which is facilitated by the use of compensators.

The reliability and simplicity of the design of the claimed communication flame arrester is confirmed by the results of numerous explosion tests and operation in industrial conditions.

Claims (2)

1. A communication flame arrester comprising a housing with flanges, flame-extinguishing elements, characterized in that the housing consists of at least one inlet and at least one outlet tee, between which at least one flame-extinguishing element is located, and at least one explosion safety valve is located on the free openings of the inlet and outlet tees. 2. A communication flame arrester according to item 1, characterized in that the flame extinguishing elements are additionally equipped with compensators.